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Gene therapy
• Gene therapy:
– to correct a genetic defect by transferring of a functional normal
copy of the gene into cells
• Examples of diseases caused by genetic defect
– Ornithine transcarbamylase (OTC deficiency)
– Hemophilia (blood coagulation factors VIII or IX)
– SCID( severe combined immunodeficiency)
– Muscular dystrophy
– Cystic fibrosis
– Sickle cell anemia
Application of gene therapy
• Genetic disorder (deficiency): OTC
• Cancer
– Genetic predisposition
– Mutation in oncogene or tumor suppressor gene
• Autoimmunity diseases: rheumatoid arthritis
– Delivery of counteracting gene
• Diseases involve several genes and the
environmental interact: diabetes
Factors to be considered in Gene therapy
• How to deliver genes to specific cells, tissue and whole
animals? (methods of delivery)
• How much and how long the introduced gene will be
expressed?
• The site and dose of gene delivery
• Is there any adverse immunological consequence of both
delivery vehicle (Virus) and the gene in animals?
• Is there any toxic effects?
Methods of gene delivery
• Viral Vectors:
–
–
–
–
–
Adenovirus
Retrovirus
Lentivirus
Adeno-associated virus (AAV)
Herpes simplex virus (HSV)
• Non-viral vector based
– Naked DNA (plasmid DNA): injection or genegun
– Liposomes (cationic lipids): mix with genes
• Ex-vivo
• In vivo
Why use viral vectors
• Virus are obligate intracellular parasites
• Very efficient at transferring viral DNA into host
cells
• Specific target cells: depending on the viral
attachment proteins (capsid or glycoproteins)
• Gene replacement: non-essential genes of virus
are deleted and exogenous genes are inserted
Generation of viral vector for gene therapy
• Replication-competent virus
• Replication-defective virus
– Amplicon: doesn’t encode structural proteins
– Can’t replicate beyond the first cycle of infection
• Elements needed to generate amplicon
– Transfer Vector: plasmid (promoter, gene of interest, ori,
packaging signal)
– Packaging vector (cosmid or cell lines): provide the viral
structural proteins for packaging of transfer vector
– Helper virus (packaging of transfer vector): deleted
Packaging signal sequence
The Ideal Vector for Gene Transfer
•
High concentration of virus allowing many cells to be infected or transduced
•
Convenience and reproducibility of production
•
Ability to transduce dividing and non-dividing cells
•
Ability to integrate into a site-specific location in the host chromosome, or to be
successfully maintained as stable episome
•
A transcriptional unit that can respond to manipulation of its regulatory elements
•
Ability to target the desired type of cell
•
No components that elicit an immune response
Adenovirus particle structure:
• Nonenveloped particle
• Contains linear double
stranded DNA
• Does not integrate into the
host genome
• Replicates as an episomal
element in the nucleus
Adenoviral vectors:
• Double-stranded DNA viruses, usually cause benign respiratory disease; serotypes
2 and 5 are used as vectors.
• Can infect dividing and non-dividing cells, can be produced at high titers.
• Replication-deficient adenovirus vectors can be generated by replacing the E1 or E3
gene, which is essential for replication.
• The recombinant vectors are then replicated in cells that express the products of the
E1 or E3 gene and can be generated in very high concentrations.
• Cells infected with recombinant adenovirus can express the therapeutic gene, but
because essential genes for replication are deleted, the vector can’t replicate.
Early generations of adenoviral vectors
(replication defective)
Gutless Adenoviral vector (Amplicon)
Characteristics of adenoviral vector
• Advantages
–
–
–
–
High titers
Both dividing and non-dividing cells
Wide tissue tropism
Easily modify tissue tropism
• Disadvantages
–
–
–
–
Transient expression ( not good for genetic diseases)
Highly immunogenic
High titers of virus can be toxic
More suitable for cancer immunotherapy
Adenoviral vectors- Limitations
• Adenoviral vectors can infect cells in vivo, causing them to express high levels of the
transgene. However, expression lasts for only a short time (5-10 days post-infection).
• Immune response is the reason behind the short-term expression.
• Immune reaction is potent, eliciting both the cell-killing “cellular” response and the
antibody producing “humoral “ response.
• Humoral response results in generation of antibodies to adenoviral proteins and
prevents any subsequent infection if a second injection of the recombinant adenovirus is
given.
Modification of the tropism of
adenovirus vector
• Adenovirus fiber binds to CAR (coxsakie and
adenovirus receptor, CAR), receptor which is
ubiquitous
• Modify the fiber protein
Death of 18-year old Jesse Gelsinger
• Liver disease: OTC deficiency (genetic disease)
• University of Pennsylvania
• High dose of adenoviral vector (E1 and E4 genes
deleted ) carrying the normal copy of OTC gene was
administered
• Suspected cause of death
• Toxicity of high titer adenoviral vector
• High immunogenicity of adenoviral vector (an immune
revolt)
Adeno-associated viral vectors:
• AAV is a simple, non-pathogenic, single stranded DNA virus dependent on the
helper virus (usually adenovirus) to replicate.
• It has two genes (cap and rep), sandwiched between inverted terminal repeats that
define the beginning and the end of the virus and contain the packaging sequence.
• The cap gene encodes viral capsid proteins and the rep gene product is involved in
viral replication and integration.
• It can infect a variety of cell types and in the presence of the rep gene product, the
viral DNA can integrate preferentially into human chromosome 19.
• To produce an AAV vector, the rep and cap genes are replaced with a transgene.
• The total length of the insert cannot exceed 4.7 kb, the length of the wild type genome.
• Production of the recombinant vector requires that rep and cap are provided in trans
along with the helper virus gene products.
• The current method is to cotransfect two plasmids, one for the vector and another for
rep and cap into cells infected with adenovirus.
• This method is cumbersome, low yielding and prone to contamination with adenovirus
and wild type AAV.
• Interest in AAV vectors is due to their integration into the host genome allowing
prolonged gene expression.
Adeno-associated virus vectors:
Advantages:
All viral genes removed
Safe
Transduction of nondividing cells
Stable expression
Disadvantages:
Small genome limits size of foreign DNA
Labor intensive production
Status of genome not fully elucidated
Generation of adeno-associated virus vector
Characteristics of AAV vector
• Advantages
– Integration and persistent expression
– No insertional mutagenesis
– Infecting dividing and nondividing cells
– Safe
• Disadvantages
– Size limitation, 4.9 kb
– Low titer of virus, low level of gene expression
Retroviruses
(including Lentivirus, HIV and MMLV based vectors)
•Single stranded RNA genome
•Lipid membrane enveloped
•Host range determined by envelope proteins
Retrovirus
ssRNA Genome
Reverse Transcription
into dsDNA
Random integration
into host genome
Host DNA
Host Cell
The Retroviral Genome
LTR
LTR
gag
pol
env
Long Terminal Repeat (LTR): Necessary for integration into host genome
(Psi): packaging signal
gag: Packages viral genome into viral particles
pol: viral polymerase necessary for viral replication
env: viral envelope proteins, necessary for entry into host cells, dictate host range
Retroviral vectors:
• Retroviral vectors are based on Moloney murine leukemia virus (Mo-MLV)
which is capable of infecting
both mouse and human cells.
• The viral genes, gag, pol and env, are replaced with the
and expressed on plasmids in the packaging cell line.
transgene of interest
• Because the non-essential genes lack the packaging
not included in the virion particle.
sequence, they are
• To prevent recombination resulting in replication competent retroviruses, all
regions of homology with the
vector backbone is removed.
Replication Deficient Viral Vectors: Genetically Engineered So The
Viral Infection Cannot Spread
•The viral DNA does not contain the viral genes needed to make more
viruses.
Viral DNA
Gene of Interest
Target Cell
Virus
Target Cell Infected With Viral
DNA Containing The Gene of
Interest
Cell’s DNA
No New Viral Particles are Created
Infection dose not spread
Rescue of Replication Deficient Viruses
by superinfection with Wild Viruses
Viral DNA
Gene of Interest
Target Cell
Virus
Wild
Virus
Cell’s DNA
Complementation:
The genome from the wild virus provides the missing proteins
needed for the viral vector to replicate. The superinfected cell
functions similarly to a packaging line.
Rescue of Replication Deficient Viruses
by superinfection with Wild Viruses
Viral DNA
Gene of Interest
Target Cell
Virus
Wild
Virus
Cell’s DNA
Recombination:
The genome from the wild virus randomly recombines with the
viral vector, providing sufficient genetic material for the viral
vector to replicate. The resulting rescued virus may possess pieces
of the original insert gene. The viral genome is impossible to
predict due to random recombination. The virus may exhibit
altered virulence.
Design of Replication Incompetent Lentiviral
Vectors (3rd Generation)
The viral vector is “gutted” as much as possible to create room for the
insert gene and to divide the viral genome into cis- and trans- acting
regions
Promoter and Insert Gene
LTR∆
gag
Transfer
Vector
Regulatory Signals
(LTR and ),
promoter and
Insert Gene
pol
Packaging
Vector
Structural &
Packaging Genes
(may already be
present in packaging
line)
env
LTR ∆
Modified LTR
To impede the
Virus from
Performing more
Than one round
Of reverse
Transcription
Envelope
Vector
Viral envelope
protein alters host
range of the viral
vector
“self inactivating”
Packaging Recombinant Lentiviral Particles
The three plasmids
containing the viral
genome components
are transfected into the
packaging line to create
the infectious viral
particles.
Multiple plasmids are
used so multiple
recombination events
would be required to
reconstitute a
replication competent
virus.
www.sigma.com/RNAI
Risks Associated with Retroviruses: Insertional Mutagenesis
Viral DNA
Gene of Interest
Virus
Target Cell
Host Cell DNA
Oncogene
Proto-Oncogene
Random integration of viral genome may
disrupt endogenous host genes. Of special concern
Is disruption of proto-oncogenes, which can lead
to increased cancer risk.
Risks Associated with Retroviral Vectors: Viral
Transduction
Viral DNA
Gene of Interest
Target Cell
Virus
Target Cell Infected With Viral
DNA Containing The Gene of
Interest
Cell’s DNA
Individuals infected with the viral vector may
express the insert gene at the site of infection.
Retroviral vectors- Limitations
• A critical limitation of retroviral vectors is their inability to infect nondividing cells,
such as those that make up muscle, brain, lung and liver tissue.
• The cells from the target tissue are removed, grown in vitro and infected with the
recombinant vector, the target cells are producing the foreign protein are then
transplanted back into the animal (ex vivo gene therapy).
• Problems with expression being shut off, prolonged expression is difficult to attain.
• Expression is reduced by inflammatory interferons acting on viral LTRs, as the
retroviral DNA integrates, viral LTR promoters are inactivated.
• Possibility of random integration of vector DNA into the host chromosome.
Characteristics of retroviral vector
• Advantages
– Integration: permanent expression
– Pseudotyped virus
• Disadvantages
– Only infecting dividing cells
– Insertional mutagenesis (tumor formation)
• Activate oncogenes
• Inhibit tumor suppressor genes
Lentiviral Vectors:
• Belong to the retrovirus family but can infect both dividing and non-dividing cells.
• They are more complicated than retroviruses, containing an additional six proteins, tat,
rev, vpr, vpu, nef and vif.
• Human immunodeficiency virus (HIV) has been disabled and developed as a vector
for in vivo gene delivery.
• Low cellular immune response, thus good possibility for in vivo gene delivery with
sustained expression over six months.
• No potent antibody response.
Likely Symptoms of Lab Acquired Infections
with Retro/Lentiviral Vectors
•Fever / flu-like symptoms
•Possible inflammation of infected tissues
•Random integration of viral genome into host genome can result
in insertional mutagenesis and oncogenesis (see slide 15)
•Expression of insert genes in infected tissues (oncogenes,
inflammatory mediators and toxins are of special concern) (see
slide 16)
The First Case
• The first gene therapy was performed on
September 14th, 1990
– Ashanti DeSilva was treated for SCID
• Sever combined immunodeficiency
– Doctors removed her white blood cells, inserted
the missing gene into the WBC, and then put
them back into her blood stream.
– This strengthened her immune system
– Only worked for a few months
A case of leukemia in a SCID child treated with a
retroviral vector
• SCID disease or ‘Bubble boy disease’ ( T cell deficiency)
• Overall quite successful, over 1000 peoples received
retroviral gene therapy
• A French baby’s treated with retroviral vector 3 years ago
• A leukemia-like illness developed this summer.
• Nine other children treated same time show no sign of
leukemia
• But the side effect isn’t a big enough risk yet that genetic
experiments for children with an often fatal immune
disease should stop
• People receiving retroviral gene therapy should be warned
about the risk of developing leukemia
Successful One Year Gene Therapy Trial
For Parkinson's Disease
• Neurologix a biotech company announced that they have
successfully completed its landmark Phase I trial of gene
therapy for Parkinson's Disease using AAV vectors.
• This was a 12 patient study with four patients in each of three
dose escalating cohorts. All procedures were performed
under local anesthesia and all 12 patients were discharged
from the hospital within 48 hours of the procedure, and
followed for 12 months. Primary outcomes of the study
design, safety and tolerability, were successfully met. There
were no adverse events reported relating to the treatment.